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Development of Blood Vessels

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Presentation on theme: "Development of Blood Vessels"— Presentation transcript:

1 Development of Blood Vessels
Blood vessel formation (angiogenesis) starts at the beginning of the third week. Blood vessels first start to develop in the extraembryonic mesoderm of the yolk sac, connecting stalk, and chorion. Blood vessels begin to develop in the embryo about two days later.

2 Production of Blood Production of blood (hemopoiesis or hematopoiesis) begins first in the yolk sac wall about the third week of development. Erythrocytes produced in the yolk sac have nuclei. Blood formation does not begin inside the embryo until about the fifth week. Erythrocytes produced in the embryo do not have nuclei (eunucleated). Hematopoiesis inside in the embryo occurs first in the liver, then later in the spleen, thymus, and bone marrow.

3 Vitelline circulation refers to the system of blood flowing from the embryo to the yolk sac and back again. The yolk-sac is situated on the ventral aspect of the embryo; it is lined by endoderm, outside of which is a layer of mesoderm. It is filled with fluid, the vitelline fluid, which possibly may be utilized for the nourishment of the embryo during the earlier stages of its existence.

4 Blood is conveyed to the wall of the sac by the primitive aortæ, and after circulating through a wide-meshed capillary plexus, is returned by the vitelline veins to the tubular heart of the embryo. This constitutes the vitelline circulation, and by means of it nutritive material is absorbed from the yolk-sac and conveyed to the embryo.

5 Cardinal veins Cardinal veins Scheme of arrangement of parietal veins. During development of the veins, the first indication of a parietal system consists in the appearance of two short transverse veins, the ducts of Cuvier, which open, one on either side, into the sinus venosus. Each of these ducts receives an ascending and descending vein. The ascending veins return the blood from the parietes(hollow organs) of the trunk and from the Wolffian bodies, and are called cardinal veins.

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10 Oxygenated blood returns from the placenta by the umbilical vein.
Half of the blood passes through the liver whereas the other half bypasses the liver by the ductus venosus. Blood enters into the inferior vena cava and then the right atrium of the heart. This blood is now partially deoxygenated because it is mixed with returning blood from the lower portion of the body and the abdominal organs. Most of the blood in the right atrium passes through the foramen ovale into the left atrium and mixes with the blood returning from the lungs (deoxygenated).

11 From the left atrium, blood passes into the left ventricle and the ascending aorta.
Arteries to the heart, head and neck, and upper limbs receive well-oxygenated blood. A small amount of blood from the right atrium mixes with blood from the superior vena cava and coronary sinus. It passes into the right ventricle and leaves via the pulmonary trunk.

12 Most of it passes into the ductus arteriosus into the aorta
Most of it passes into the ductus arteriosus into the aorta. A small amount passes into the lungs. 50% of the blood passes via the umbilical arteries into the placenta for reoxygenation, the rest supplies the viscera and the inferior 1/2 of the body.

13 After birth, the foramen ovale, ductus arteriosus, ductus venosus and umbilical vessels are no longer needed and they close. The right ventricular wall is thicker in the newborn but by the end of month 1, the left ventricular wall is thicker.

14 The fetal circulation is designed to carry oxygenated blood from the placenta to the fetal circulation, bypassing the lungs. Changes that will result in a normal adult circulation occurs during infancy. Defects will commonly involve a patent foramen ovale

15 CARDIOVASCULAR EMBRYOLOGY
The cardiovascular system begins to develop during week 3. Mesenchymal cells derived from the mesoderm form endothelial tubes which join to form the primitive vascular system.

16 HEART DEVELOPMENT (WEEK 3)
Heart develops from splanchnic mesenchyme in the cardiogenic area. Bilateral cardiogenic cords are formed from the mesenchyme become canalized and form the paired endocardial heart tubes These fuse into a single heart tube forming the primitive heart

17 Surrounding mesenchyme thicken to form the myoepicardial mantle (future myocardium and epicardium) separated from the endothelial heart tube (future endocardium) by the gelatinous cardiac jelly. The future heart develops dilatations and constrictions resulting in 4 chambers sinus venosus primordial atrium ventricle bulbus cordis

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19 The truncus arteriosus is continuous caudally with the bulbus cordis, and enlarges cranially to form the aortic sac from which the aortic arches arise

20 The sinus venosus receives (the umbilical veins from the chorion.
the vitelline veins from the yolk sac the common cardinal veins from the embryo.

21 3 systems of paired veins drain into the primitive heart:
the vitelline system will become the portal system; the cardinal veins will become the caval system; the umbilical system which degenerates after birth

22 The bulbus cordis and the ventricle grow faster and the heart bends upon itself, forming a bulboventricular loop. The atrium and sinus venosus come to lie dorsal to the bulbus cordis, truncus arteriosus and ventricle. At the same time, the heart invaginates into the pericardial cavity. The dorsal mesocardium which attaches it to the dorsal wall of the pericardial cavity degenerates and forms the tranverse pericardial sinus

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24 First heartbeat occurs at 21 to 22 days and originates in the muscle, forming peristalsis-like waves beginning in the sinus venosus.

25 By the end of week 4 coordinated contractions of the heart results in unidirectional flow:
Blood enters the sinus venosus from the vitelline, cardinal and umbilical veins. Blood flows into the primitive ventricle; Upon ventricular contraction, blood flows into the bulbus cordis and the truncus arteriosus into the aortic sac, passing into the aortic arches and branchial arches; Blood then passes to the dorsal aortae for distribution to the embryo, yolk sac and placenta.

26 The heart divides into 4-chambered heart between weeks 4 and 7.

27 Endocardial cushions form on the dorsal and ventral walls of the atrioventricular canal.
At week 5, they approach each other and fuse, dividing the atrioventricular canal into right and left canals.

28 Atria are partitioned successively by the septum primum and the septum secundum.
The latter is an incomplete partition and leaves a foramen ovale. The foramen ovale has a valve formed from the degeneration of the cranial portion of the septum primum.

29 Before birth the foramen ovale allows blood to pass from the right atrium into the left atrium; reflux is prevented by the valve. After birth the foramen ovale normally closes by fusion of the septum primum and the septum secundum.

30 The sinus venosus develops a left horn which becomes the coronary sinus and a right horn which will be incorporated into the right atrium. The smooth part of the right atrium, the sinus venarum, is derived from the sinus venosus whereas the muscular part, the auricle, is derived from the primitive atrium. The 2 portions are separated internally by the crista terminalis and externally by the sulcus terminalis.

31 The primitive pulmonary vein and its 4 main branches become partially incorporated into the left atrium. This results in the 4 pulmonary veins. The portion derived from the original left atrium retains a trabeculated apperance.

32 The ventricles become partitioned by a crescentic fold which is open cranially until the end of week 7. The interventricular septum is formed of a central membranous part and a surrounding muscular part. After closure, the right ventricle communicates with the pulmonary trunk and the left ventricle with the aorta.

33 During week 5, the bulbus cordis and the truncus arteriosus become divided by an aorticopulmonary septum into the definitive pulmonary trunk and aorta. Valves develop from proliferation of the subendocardial tissue.

34 The primitive atrium acts as a temporary pacemaker
The primitive atrium acts as a temporary pacemaker. But the sinus venosus soon takes over. The sinuatrial (SA) node develops during week 5. It is part of the sinus venosus which becomes incorporated into the right atrium. The atrioventricular (AV) node also develops from the cells in the wall of the sinus venosus together with cells from the atrioventricular canal region. The critical period of development is from day 20 to day 50 after fertilization.

35 Improper partitioning of the heart may result in defects of the cardiac septa, of which the ventricular septal defects are most common (25% of congenital heart disease).

36 Membranous ventricular septal defect (most common):
involves the oval membranous portion of the interventricular septum which fails to develop. is due to the failure of extensions of subendocardial tissue growing from the right side of the fused endocardial cushions and fusing with the aorticopulmonary septum and the muscular part of the interventricular septum.

37 Muscular septal defect:
Perforation may appear anywhere in the muscular part of the interventricular septum (multiple defects = Swiss cheese type of ventricular septal defect) due perhaps to excessive resorption of myocardial tissue during formation of the muscular part of the interventricular septum. Absence of interventricular septum is rare and results in a 3-chambered heart called cor triloculare biatriatum

38 The tetralogy of Fallot consists of
pulmonary valve stenosis: the cusps of pulmonary valve are fused together to form a dome with a narrow central opening. ventricular septal defect overriding aorta hypertrophy of right ventricle Cyanosis is an obvious sign but may not be present at birth.

39 Aortic arches When the branchial arches form during week 4 and 5, they are penetrated by arteries arising from the aortic sac, which are called the aortic arches. During week 6 to 8 the primitive aortic arch pattern is transformed into the adult arterial arrangement of carotid, subclavian, and pulmonary arteries.

40 The lymphatic system begins to develop around week 5.
6 primary lymph sacs develop and later become interconnected by lymph vessels; lymph nodules do not appear until just before and/or after birth. Hygroma: tumor-like mass of dilated lymphatic vessels derived from the pinched-off portion of the jugular lymph sac.


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